CN212287779U - Dough cutting equipment - Google Patents

Abstract

The utility model relates to the technical field of pastry making, and discloses a dough cutting device, which solves the problems that the motor is easy to damage and the service life of the motor is reduced when a conveyor belt is frequently started and stopped in the prior conveying process, and comprises a driving mechanism, the conveyor belt and a cutting mechanism, wherein the driving mechanism comprises a driving assembly and a directional assembly, the driving assembly comprises a driving cylinder, the directional assembly comprises a one-way bearing, the driving cylinder is rotationally connected with the one-way bearing through a piston rod of the driving cylinder, the conveyor belt comprises a belt surface, a driving shaft and a driven shaft, the belt surface surrounds the driving shaft and the driven shaft, the one-way bearing is sleeved on the driving shaft, the cutting mechanism comprises a cutting assembly, the cutting assembly comprises a cutting blade, the cutting blade is lifted along the vertical direction, the driving cylinder drives the one-way bearing to rotate in a reciprocating way, the cutting effect is optimized, and the service life of the equipment is prolonged.

Description

Dough cutting equipment

Technical Field

The utility model belongs to the technical field of the technique of food preparation and specifically relates to a dough cutting equipment is related to.

Background

At present in the preparation process of flour food, cut again after need kneading into the dough with flour to make things convenient for subsequent course of working, the process of cutting the dough if accomplish through the manpower and waste time and energy, consequently a series of automatic dough cutting equipment have appeared.

For example, "an automatic dough-forming apparatus" with grant publication No. CN205124868U, which discloses an automatic dough-forming apparatus. This automatic forming device of dough adopts full-automatic mechanized structure, mixes the stirring with flour through dough stirring extruder and extrudes the dough, through conveyer belt conveying dough, the dough passes through dough cutting device and dough pusher, with dough equal proportion cutting back propelling movement to appointed position, the overall process full automatization need not the hand labor output, and production efficiency is high, and output is big, and is with low costs.

The above prior art solutions have the following drawbacks: when the cutter whereabouts cutting among the cutting device, still can lead to the dough to pile up at the cutter rear side if the conveyer belt is removing, make the shape of dough change, can influence the cutting effect of blade simultaneously, so need open through opening of infrared inductor control conveyer belt and stop, but traditional conveyer belt uses motor power supply drive, and the current impact when the motor starts to stop is great, if frequently carry out opening of conveyer belt and stop and can make the motor easily damage, reduce the life of motor.

Disclosure of Invention

Not enough to prior art exists, one of the purposes of the utility model is to provide a dough cutting equipment avoids frequently opening and stops the condition that leads to the motor to damage, makes the dough move one section distance simultaneously on the conveyer belt and can be static on the conveyer belt, cuts the dough when static, guarantees that the dough cutting levels, has optimized the cutting effect, has prolonged the life of equipment.

The above object of the present invention is achieved by the following technical solutions:

the utility model provides a dough cutting equipment, includes actuating mechanism, conveyer belt and cutting mechanism, actuating mechanism includes drive assembly and directional subassembly, drive assembly is including driving actuating cylinder, directional subassembly includes one-way bearing, it is connected with one-way bearing rotation through the piston rod that drives actuating cylinder to drive actuating cylinder, the conveyer belt is including area face, driving shaft and driven shaft, the area face encircles driving shaft and driven shaft, one-way bearing cup joints on the driving shaft, cutting mechanism includes cutting assembly, cutting assembly includes cutting blade, cutting blade goes up and down along the vertical direction, its characterized in that: the driving cylinder drives the one-way bearing to rotate in a reciprocating mode to drive the conveying belt to move intermittently, the conveying belt passes through the cutting assembly, and the cutting blade lifts and descends to cut dough on the conveying belt.

Through adopting above-mentioned scheme, the conveyer belt can make the dough move a section distance back static on the conveyer belt under the drive actuating cylinder passes through one-way bearing's drive, the dough is still moving when having avoided cutting blade cutting dough, make the dough pile up at the cutting blade rear side, the shape that leads to the dough changes, the cutting effect and the cutting efficiency of cutting equipment have been improved, simultaneously because use drive actuating cylinder to replace the motor, prevent that the phenomenon that the motor frequently opened and stop from causing cutting equipment to damage, the holistic life of cutting equipment has been prolonged simultaneously.

The present invention in a preferred example may be further configured to: the cutting assembly comprises a cutting cylinder, the cutting cylinder is fixed with a cutting blade through a piston rod of the cutting cylinder, and the cutting cylinder drives the cutting blade to lift.

Through adopting above-mentioned scheme, use cutting cylinder control cutting blade's lift, saved a large amount of manpower and materials, made the cutting operation more convenient.

The present invention in a preferred example may be further configured to: the cutting assembly comprises an installation assembly and a limiting assembly, the installation assembly comprises an installation plate, the installation plate is parallel to the conveying belt and is arranged above the conveying belt, an installation hole which vertically penetrates through the installation plate is formed in the upper surface of the installation plate, the limiting assembly comprises a limiting rod, the limiting rod is in transition fit with the installation hole, and the limiting rod is fixed on the cutting blade.

Through adopting above-mentioned scheme, restriction cutting blade is at the direction of lift removal's in-process, and the cutting position of fixed cutting blade guarantees cutting blade's cutting effect.

The present invention in a preferred example may be further configured to: be equipped with the auxiliary blade on the cutting blade, the auxiliary blade is stood vertically on the plane of cutting blade, when the cutting blade cuts the dough, the bottom surface contact area face of auxiliary blade.

By adopting the above scheme, the auxiliary blade further divides the dough while the cutting blade cuts the dough.

The present invention in a preferred example may be further configured to: the auxiliary blade is arranged in the direction that the cutting blade faces away from the conveying belt.

Through adopting above-mentioned scheme, the supplementary blade is better to the segmentation effect of dough, and the dough after cutting apart can directly fall from the conveyer belt.

The present invention in a preferred example may be further configured to: when the cutting blade cuts the dough, the bottom surface of the auxiliary blade is completely attached to the belt surface.

Through adopting above-mentioned scheme, supplementary blade laminates with the conveyer belt front end when cutting blade cutting dough, guarantees to cut off the dough completely.

The present invention in a preferred example may be further configured to: cutting mechanism includes the installation component, the installation component includes preceding safety cover and back safety cover, cutting blade quilt cover is in preceding safety cover and back safety cover, cutting blade is on the projection of horizontal direction falls into preceding safety cover and back safety cover completely.

Through adopting above-mentioned scheme, including safety cover and back safety cover protected cutting blade before using, can play dirt-proof effect on the one hand, guarantee cutting blade's cleanness, guarantee food safety, on the other hand prevents that cutting blade from causing the injury to the people, plays the effect of protection personnel safety.

The present invention in a preferred example may be further configured to: the conveyer belt includes the back shaft, back shaft and driving shaft and driven shaft parallel arrangement.

Through adopting above-mentioned scheme, the back shaft plays the supporting role to the area face, prevents that the dough overweight from leading to taking the face sunken.

In summary, the invention includes at least one of the following beneficial technical effects:

1. the driving cylinder is started and stopped to drive the conveying belt to move and stop, so that the dough can move on the conveying belt for a certain distance and can stand still on the conveying belt, the cutting cylinder drives the cutting blade to cut the static dough, the dough is cut smoothly, and the cutting effect is optimized;

2. the air cylinder replaces the motor, so that the motor cannot be damaged;

3. the auxiliary blade helps the cutting blade to further cut the dough into small pieces, so that the next processing process is facilitated, and the dough cutting efficiency is improved;

4. preceding baffle, preceding safety cover and the back safety cover that sets up can prevent cutting blade dust fall, and guarantee food safety prevents simultaneously that cutting blade from causing the injury to personnel.

Drawings

FIG. 1 is a schematic view showing the overall structure of a dough cutting apparatus.

FIG. 2 is a schematic view showing a partial structure of a dough cutting apparatus.

Fig. 3 is a schematic view of the overall structure of the fixing mechanism.

FIG. 4 is a schematic view of the conveyor belt and baffle attachment.

Fig. 5 is a schematic view of the connection of the driving cylinder to the diaphragm.

Fig. 6 is a schematic view of the drive mechanism connections.

FIG. 7 is a schematic view of the connection of the drive shaft to the bearing arm.

Fig. 8 is a schematic view of the overall structure of the cutting mechanism.

FIG. 9 is a schematic view of the cutting assembly coupled to the mounting assembly.

Fig. 10 is a schematic view of the first and second clamping plates coupled to a cutting blade.

Fig. 11 is a schematic view of the structure of the collecting mechanism.

Reference numerals: 1. a fixing mechanism; 11. supporting legs; 12. a partition plate; 121. a fixing hole; 13. a front baffle; 14. a tailgate; 15. a base plate; 16. a shutter; 2. a conveyor belt; 21. a belt surface; 22. a drive shaft; 23. a driven shaft; 24. a support shaft; 3. a drive mechanism; 31. a drive assembly; 311. a driving cylinder; 3111. a second fixed block; 3112. a cylinder fixing block; 3113. a first fixed shaft; 312. a first fixing plate; 3121. a first fixed block; 313. fixing the bolt; 32. an orientation assembly; 321. a one-way bearing; 322. a bearing arm; 3221. a second fixed shaft; 3222. a fixing ring; 4. a cutting mechanism; 41. a cutting assembly; 411. cutting the air cylinder; 4111. a fixing sheet; 4112. a first splint; 412. a cutting blade; 413. an auxiliary blade; 42. mounting the component; 421. a mounting frame; 422. mounting a plate; 4221. mounting holes; 423. a front protective cover; 424. a rear protective cover; 43. a limiting component; 431. a limiting rod; 4311. a second splint; 5. a collection mechanism; 51. a motor; 511. a second fixing plate; 52. and (4) a material twisting rod.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in the attached figure 1, for the utility model discloses a dough cutting equipment of cylinder control, including fixed establishment 1, actuating mechanism 3 and cutting mechanism 4.

As shown in fig. 3, the fixing mechanism 1 includes a support leg 11, a partition plate 12, and a bottom plate 15.

The number and shape of the supporting legs 11 can be determined by the actual situation, and here, the supporting legs 11 are rectangular solids, and the number is four. The supporting feet 11 are vertical to the horizontal plane, every two supporting feet 11 are a group, and the two groups of supporting feet 11 are parallel and opposite to each other.

Be equipped with a bottom plate 15 on the supporting legs 11, bottom plate 15 is on a parallel with the horizontal plane setting, is equipped with two baffles 12 on two long limits of bottom plate 15 respectively, and baffle 12 is vertical to be set for, and the quantity and the shape of baffle 12 can be set for according to actual conditions, and the long limit length of bottom plate 15 is good at to 12 base lengths of this place baffle, and the one end of baffle 12 aligns with bottom plate 15, and the other end stretches out outside bottom plate 15. The opposite surfaces of the two partition plates 12 are further provided with fixing holes 121 penetrating through the partition plates 12, the number of the fixing holes 121 can be set according to actual conditions, the number of the fixing holes 121 on each partition plate 12 is five, and the fixing holes 121 are arranged at intervals along the horizontal length direction of the partition plates 12.

The end of the partition board 12 extending out of the bottom board 15 is provided with a front baffle 13. The length of the front baffle 13 is the same as the distance between the two partition plates 12, two sides of the front baffle 13 are respectively connected with the front ends of the two partition plates 12 in a welding manner, and the height of the front baffle 13 is half of the height of the partition plates 12.

The length of the long edge of the upper surface of the partition board 12 is shorter than that of the long edge of the bottom surface of the partition board 12, a bevel edge is arranged on the partition board 12 on each side, the lower end of the bevel edge is arranged at the highest point of the front baffle 13, and the upper end of the bevel edge is positioned on the upper surface of the partition board 12.

Be provided with a sunshade 16 on the preceding baffle 13, the length of sunshade 16 is the same with the length of preceding baffle 13, and the both sides limit of sunshade 16 links to each other with the hypotenuse of both sides baffle 12 respectively, makes sunshade 16 be an inclined plane, and the material of sunshade 16 can be set for according to actual conditions, for transparent material, and here is transparent plastic, can observe the cutting process through sunshade 16, can prevent simultaneously that cutting mechanism 4 from causing the injury to the human body in the cutting process.

One end of each partition plate 12, which is aligned with the bottom plate 15, is provided with a rear baffle plate 14, the length of each rear baffle plate 14 is equal to the distance between the two partition plates 12, two sides of each rear baffle plate 14 are connected with the two partition plates 12 in a welded mode, and the bottom edge of each rear baffle plate 14 is connected with the bottom plate 15 in a welded mode.

As shown in fig. 2, the conveyor belt 2 is disposed between two partitions 12, and the conveyor belt 2 is parallel to the horizontal plane.

As shown in fig. 4, the conveyor belt 2 includes a belt surface 21, a driving shaft 22, a driven shaft 23, and a supporting shaft 24.

The driving shaft 22 is located on the side of the partition 12 having the oblique side, which is downstream of the conveyor 2, and the driven shaft 23 is located on the side of the conveyor 2 upstream. The number of the support shafts 24 may be set according to the length of the conveyor belt 2, where the number of the support shafts 24 is three.

The length of the driving shaft 22 is greater than the distance between the two partition plates 12, and one end of the driving shaft 22 is inserted into the fixing hole 121 of the partition plate 12 on the corresponding side and is rotatably connected with the fixing hole 121. The other end of the driving shaft 22 is inserted into the fixing hole 121 at the corresponding side to be rotatably connected with the fixing hole 121, and the end extends out of the fixing hole 121. The lengths of the driven shaft 23 and the supporting shaft 24 are greater than the distance between the two partition plates 12, and the two ends of the driven shaft 23 and the supporting shaft 24 are respectively inserted into the fixing holes 121 of the partition plates 12 on the corresponding side and are rotatably connected with the fixing holes 121, so that the driven shaft 23 and the supporting shaft 24 can smoothly rotate.

The belt surface 21 is tensioned around the driving shaft 22 and the driven shaft 23, the supporting shaft 24 is located between the belt surfaces 21 to support the belt surfaces 21, the belt surfaces 21 can be driven to move through rotation of the driving shaft 22, accordingly, the dough can be guaranteed to move smoothly on the conveyor belt 2, and the supporting shaft 24 guarantees that the dough cannot collapse when conveyed on the belt surfaces 21.

As shown in fig. 2, the driving mechanism 3 includes a driving assembly 31 and an orientation assembly 32.

As shown in fig. 5, the driving assembly 31 includes a first fixing plate 312. The first fixing plate 312 is disposed on the partition plate 12, the first fixing plate 312 is disposed perpendicular to the plane of the partition plate 12 and faces outward, the bottom surface of the first fixing plate 312 is parallel to the bottom surface of the partition plate 12, the first fixing plate 312 is further provided with two first fixing blocks 3121, the two first fixing blocks 3121 are disposed oppositely and parallel, a gap is left between the two first fixing blocks 3121, and the two first fixing blocks 3121 are coaxially provided with holes penetrating through the two first fixing blocks 3121.

The driving assembly 31 further includes a driving cylinder 311, a cylinder fixing block 3112 is disposed below the driving cylinder 311, the size of the cylinder fixing block 3112 is the same as the size of the gap between the two first fixing blocks 3121, a hole penetrating through the cylinder fixing block 3112 is formed in the cylinder fixing block 3112, the size of the hole is the same as the size of the hole in the two first fixing blocks 3121, a first fixing shaft 3113 is further disposed on the cylinder fixing block 3112, the size of the first fixing shaft 3113 is in transition fit with the hole in the cylinder fixing block 3112, the length of the first fixing shaft 3113 completely penetrates through the cylinder fixing block 3112 and the two first fixing blocks 3121, the cylinder fixing block 3112 is clamped between the two first fixing blocks 3121 by the first fixing shaft 3113 and is rotatably connected, so that the driving cylinder 311 rotates around the first fixing shaft 3113.

As shown in fig. 6, the orientation assembly 32 includes a one-way bearing 321 and a bearing arm 322, a fixing ring 3222 is disposed at one end of the bearing arm 322, an inner diameter of the fixing ring 3222 is the same as an outer diameter of the one-way bearing 321, and the one-way bearing 321 is sleeved with the fixing ring 3222, so that the bearing arm 322 is rotatably connected to the one-way bearing 321. The other end of the bearing arm 322 is provided with a hole penetrating through the bearing arm 322, and the other end is further provided with a second fixing shaft 3221 in transition fit with the hole.

The piston rod of the driving cylinder 311 is further provided with two second fixing blocks 3111, the two second fixing blocks 3111 are disposed oppositely and parallel, a gap is reserved between the two second fixing blocks 3111, the gap between the two second fixing blocks 3111 is the same as the width of the bearing arm 322, holes penetrating through the two second fixing blocks 3111 are coaxially disposed on the two second fixing blocks 3111, the holes are in transition fit with the second fixing shaft 3221, the bearing arm 322 is inserted between the two second fixing blocks 3111 by penetrating through the bearing arm 322 and the two second fixing blocks 3121 by the second fixing shaft 3221, and the bearing arm 322 is rotatably connected with the two second fixing blocks 3111, so that the bearing arm 322 rotates around the second fixing shaft 3221.

As shown in fig. 7, a hole is formed at one end of the bearing arm 322, which is sleeved on the one-way bearing 321, and the size of the hole is the same as the inner diameter of the one-way bearing 321, the positioning component 32 and the part of the driving shaft 22, which extends out of the fixing hole 121, are sleeved through the hole, the one-way bearing 321 is clamped between the fixing ring 3222 and the driving shaft 22 and is rotatably connected with the fixing ring, when the driving cylinder 311 operates, the bearing arm 322 is driven to rotate, and thus the driving shaft 22 is driven to rotate by the bearing arm 322, but due to the arrangement of the one-way bearing 321, the driving shaft 22 can only rotate in one direction, and the conveyor.

As shown in fig. 2 and 8, the cutting mechanism 4 is disposed above the conveyor belt 2, and the cutting mechanism 4 is perpendicular to the horizontal plane.

The cutting mechanism 4 includes a mounting assembly 42, a cutting assembly 41, and a stop assembly 43. The mounting assembly 42 includes two mounting frames 421 and two mounting frames 422, and the two mounting frames 421 are respectively disposed on the partition boards 12 at two sides perpendicular to the horizontal plane. The fixed mounting plate 422 is connected to two mounting brackets 421 upper end, and the mounting plate 422 is parallel to the horizontal plane setting, and length is the same with the length between two baffle 12.

As shown in fig. 8 and 9, the mounting plate 422 is provided with three mounting holes 4221 on the upper surface thereof, and the mounting holes 4221 are spaced apart from each other along the horizontal length direction of the mounting plate 422.

The cutting assembly 41 includes a cutting cylinder 411 and a cutting blade 412. The cutting cylinder 411 stands vertically on the mounting hole 4221 in the middle of the mounting plate 422, both sides of the lower end of the cutting cylinder 411 are outwards provided with fixing pieces 4111, the fixing pieces 4111 are parallel to the mounting plate 422 and tightly attached to the upper surface of the mounting plate 422, and the fixing pieces 4111 are screwed tightly and fixed on the mounting plate 422 through screws so as to fix the cutting cylinder 411.

The size of the piston rod in the cutting cylinder 411 is in transition fit with the size of the mounting hole 4221, the piston rod of the cutting cylinder 411 downwards penetrates through the mounting hole 4221, and the bottom end of the cutting cylinder 411 is further provided with two first clamping plates 4112. The two first clamping plates 4112 are oppositely arranged and parallel.

The limiting assembly 43 further comprises two limiting rods 431, the two limiting rods 431 respectively vertically penetrate through the two mounting holes 4221 of the mounting plate 422, two second clamping plates 4311 are arranged at the bottom of each limiting rod 431, and the two second clamping plates 4311 are oppositely arranged and parallel.

As shown in fig. 10, the gap between the two first clamping plates 4112 is the same as the thickness of the cutting blade 412, and a plurality of bolts and nuts are provided on the two first clamping plates 4112, and the bolts pass through the two first clamping plates 4112 and the cutting blade 412, so that the cutting blade 412 is locked between the two first clamping plates 4112 by the bolts and the nuts.

The gap between the two second clamping plates 4311 is the same as the thickness of the cutting blade 412, the position of the second clamping plate 4311 is on the same horizontal plane with the position of the first clamping plate 4112, and a plurality of bolts and nuts are arranged on the two second clamping plates 4311, the bolts pass through the two second clamping plates 4311 and the cutting blade 412, and the cutting blade 412 is locked between the two first clamping plates 4112 by the bolts and the nuts.

The cutting blade 412 is further provided with auxiliary blades 413, the number and the shape of the auxiliary blades 413 can be set according to actual conditions, and the number of the auxiliary blades 413 is three.

As shown in fig. 2, the auxiliary blade 413 is perpendicular to the plane of the cutting blade 412 and is directed away from the conveyor belt 2. The bottom surface of the auxiliary blade 413 can also abut the conveyor belt 2 when the cutting blade 412 cuts the dough. The bottom surface of auxiliary blade 413 is the cambered surface, and the radian is the same with the radian of conveyer belt 2 front end for when auxiliary blade 413 and conveyer belt 2 butt, the lower limb of auxiliary blade 413 is laminated with conveyer belt 2 completely, is convenient for cut off the dough, makes the dough by further cutting into the fritter.

As shown in fig. 8, the mounting assembly 42 further includes a front protection cover 423 and a rear protection cover 424, which are respectively disposed on the front side and the rear side of the cutting blade 412, and are parallel to the blade surface of the cutting blade 412, the length of the front protection cover 423 and the length of the rear protection cover 424 are the same as the length of the mounting plate 422, the width of the front protection cover is the same as the length of the long edge of the mounting frame 421, the material of the front protection cover 423 and the rear protection cover 424 can be determined according to the actual situation, the material of the front protection cover 423 and the rear protection cover 424.

As shown in fig. 2 and 11, a collecting mechanism 5 is further disposed at the foremost end of the conveyor belt 2, and the collecting mechanism 5 includes a motor 51, a second fixing plate 511 and a material twisting rod 52.

The second fixing plate 511 is disposed on the partition 12 at one side, the second fixing plate 511 is disposed perpendicularly to the plane of the partition 12 to the outside, the bottom surface of the second fixing plate 511 is parallel to the bottom surface of the partition 12, and the motor 51 is fixed to the second fixing plate 511.

The length of the material twisting rod 52 is slightly longer than the distance between the two partition plates 12, the number of the material twisting rods 52 is two, one end of each material twisting rod 52 penetrates through the partition plates 12 and is arranged in parallel to the horizontal plane, the two material twisting rods 52 are all sleeved with gears, the two material twisting rods 52 are connected through the gears, one material twisting rod 52 is connected with the motor 51 in a rotating mode after being sleeved with the gears, and the motor 51 rotates to drive the two material twisting rods 52 to rotate.

The implementation principle of the embodiment is as follows:

when the dough moves on conveyer belt 2, start through driving actuating cylinder 311 and stop the motion that drives conveyer belt 2 and stop, make the dough can move one section distance and can be static on conveyer belt 2, the position back of dough has been fixed, cutting cylinder 411 drives cutting blade 412 and cuts the dough when static, guarantee that the dough cutting is level and smooth, the cutting effect has been optimized, the auxiliary blade 413 of setting helps cutting blade 412 further to cut into the fritter with the dough, make things convenient for processing procedure on next step, the efficiency of dough cutting has been improved, simultaneously because replaced the motor with the cylinder, the condition that the motor damaged can not appear, the dough is transported to further course of working through hank material pole 52 after being cut.

The embodiments of the present invention are preferred embodiments of the present invention, and the scope of the present invention is not limited by these embodiments, so: all equivalent changes made according to the structure, shape and principle of the invention are covered by the protection scope of the invention.

Claims (8)

1. A dough cutting equipment, includes actuating mechanism (3), conveyer belt (2) and cutting mechanism (4), actuating mechanism (3) includes drive assembly (31) and directional subassembly (32), drive assembly (31) is including driving actuating cylinder (311), directional subassembly (32) are including one-way bearing (321), drive actuating cylinder (311) and one-way bearing (321) through the piston rod that drives actuating cylinder (311) rotate to be connected, conveyer belt (2) is including taking face (21), driving shaft (22) and driven shaft (23), take face (21) to encircle driving shaft (22) and driven shaft (23), one-way bearing (321) cup joints on driving shaft (22), cutting mechanism (4) is including cutting subassembly (41), cutting subassembly (41) includes cutting blade (412), cutting blade (412) are gone up and down along the vertical direction, the method is characterized in that: drive actuating cylinder (311) and drive one-way bearing (321) and carry out reciprocating motion, drive conveyer belt (2) intermittent type removes, conveyer belt (2) are through cutting subassembly (41), cutting blade (412) go up and down to carry out the cutting to the dough on conveyer belt (2).

2. The dough cutting apparatus of claim 1, wherein: the cutting assembly (41) comprises a cutting air cylinder (411), the cutting air cylinder (411) is fixed with the cutting blade (412) through a piston rod of the cutting air cylinder (411), and the cutting air cylinder (411) drives the cutting blade (412) to ascend and descend.

3. The dough cutting apparatus of claim 1, wherein: cutting assembly (41) are including installation component (42) and spacing subassembly (43), installation component (42) are including mounting panel (422), conveyer belt (2) top is located in conveyer belt (2) is on a parallel with in mounting panel (422), mounting panel (422) upper surface is equipped with vertical ann and runs through mounting hole (4221) of mounting panel (422), spacing subassembly (43) are including gag lever post (431), gag lever post (431) and mounting hole (4221) transitional fit, gag lever post (431) are fixed on cutting blade (412).

4. The dough cutting apparatus of claim 1, wherein: an auxiliary blade (413) is arranged on the cutting blade (412), the auxiliary blade (413) is vertically arranged on the plane of the cutting blade (412), and when the cutting blade (412) cuts the dough, the bottom surface of the auxiliary blade (413) contacts the belt surface (21).

5. The dough cutting apparatus of claim 4, wherein: the auxiliary blade (413) is arranged in the direction in which the cutting blade (412) is conveyed away from the conveyor belt (2).

6. The dough cutting apparatus of claim 5, wherein: when the cutting blade (412) cuts the dough, the bottom surface of the auxiliary blade (413) completely abuts against the belt surface (21).

7. The dough cutting apparatus of claim 1, wherein: cutting mechanism (4) are including installation component (42), installation component (42) are including preceding safety cover (423) and back safety cover (424), cutting blade (412) are covered in preceding safety cover (423) and back safety cover (424), cutting blade (412) projection on the horizontal direction falls into on preceding safety cover (423) and back safety cover (424) completely.

8. The dough cutting apparatus of claim 1, wherein: the conveyor belt (2) comprises a support shaft (24), and the support shaft (24) is arranged in parallel with the driving shaft (22) and the driven shaft (23).

Images